Prevention by the MER tubercle bacillus fraction of immunosuppression induced by cancer chemotherapeutic agents

Summary Contact hypersensitivity (CH) to 2,4-dinitro-1-fluorobenzene (DNFB) was induced in guinea pigs and mice by DNFB skin application. Development of CH was suppressed in both species either by cyclophosphamide (CY) treatment after sensitization or by single intravenous injection of dinitrobenzene-sulfonate (DNBS) before sensitization (hapten-induced tolerance). Additional treatment schedules were employed in guinea pigs, with the following results: Suppression of CH by injection of DNBS concomitant with sensitization; abrogation of hapten-induced tolerance by administration of CY before sensitization; and potentiation of CH skin reactivity by administration of CY before sensitization.Pretreatment by two injections of the methanol extraction residue (MER) tubercle bacillus fraction restored significantly the ability of CY treated animals to respond to DNFB sensitization. In contrast, administration of MER either by one injection before sensitization, concomitant with DNFB, or after sensitization did not prevent immunosuppression by CY.MER treatment was not effective in reversing hapten-induced tolerance in mice, and had only an occasional effect on this process in guinea pigs. Abrogation of hapten-induced tolerance and potentiation of DNFB sensitization by CY in guinea pigs were also not influenced by MER treatment.Supported by Contract NO1-CM-12127 from the NCI and by research grants from Concern Foundation, Inc., the Lautenberg Endowment, the National Council for Research and Development, Israel, and the GSF Munich, Germany, and the Leukemia Research Foundation, Inc.     

Leaf pretreatment with senescence retardants as a basis for oat protoplast improvement

Protoplasts obtained from oat leaves floated on buffer for 18hr show high nuclease activity, low rates of incorporation ofamino acids and nucleosides into macromolecules, and high ratesof spontaneous lysis. Addition to the leaf flotation mediumof the senescence retardants cycloheximide or kinetin, of thedibasic amino acids L-lysine or L-arginine, or of the diaminesputrescine or cadaverine reduces the rise in nuclease activityand spontaneous lysis of protoplasts, and increases the rateor extent of presumptive protein and nucleic acid synthesis.The diamines, which also retard chlorophyll degradation in theexcised leaves, appear to act both on the membrane and on systemscontrolling macromolecular synthesis and breakdown. By contrast,the senescence promoter L-serine hastens chlorophyll degradationfrom excised leaves and does not improve protoplasts derivedfrom those leaves. (Received July 4, 1977; )     

Surgical Management of Epilepsy

Therapy with anticonvulsant drugs reduces the frequency and severity of seizures in many but not all epileptic patients. Unfortunately, in a significant number control remains poor even when maximal doses of multiple anticonvulsant drugs are given. Some of these patients are candidates for surgical treatment of epilepsy. The operative management of convulsive disorders is a well-established technique and is available in some centers. In selected cases, such operations are both safe and effective, with good longterm improvement or complete control in 76 percent of patients. We have summarized the 24-year experience with surgical operation for epilepsy at the University of Washington Medical Center.     

Plants interact with microbial polysaccharides

Plants are resistant to almost all of the microorganisms with which they come in contact. In response to invasion by a fungus, bacterium, or a virus, many plants produce low molecular weight compounds, phytoalexins, which inhibit the growth of microorganisms. Phytoalexins are produced whether or not the invading microorganism is a pathogen. The production of phytoalexins appears to be a widespread mechanism by which plants attempt to defend themselves against pests. Molecules of microbial origin which trigger phytoalexin accumulation in plants are called elicitors. Structural polysaccharides from the mycelial walls of several fungi elicit phytoalexin accumlation in plants. Approximately 10 ng of the polysaccharide elicits the accumulation in plants of more than sufficient amounts of phytoalexin to stop the growth of microorganisms in vitro. The best characterized elicitors have been demonstrated to be β-1,3-glucans with branches to the 6 position of some of the glucosyl residues. Oligosaccharides, produced by partial acid hydrolysis of the mycelial wall glucans, are exceptionally active elicitors. The smallest oligosaccharide which is still an effective elicitor is composed of about 8 sugar residues. Bacteria also elicit phytoalexin accumulation in plants, but the Rhizobium symbionts of legumes presumably have a mechanism which allows them to avoid either eliciting phytoalexin accumulation or the effects of the phytoalexins if they are accumulated. The lectins of legumes bind to the lipopolysaccharides of their symbiont, but not of their non-symbiont, Rhizobium. It is not known whether the lectin-lipopolysaccharide interaction is involved with the establishment of symbiosis. However, evidence will be presented that suggests that lectins are, in fact, enzymes capable of modifying the structurs of the lipopolysaccharides of their symbiont, but not of their non-symbiont, Rhizobium. It will also be shown that the lipopolysaccharides isolated from different Rhizobium species and from different strains of individual Rhizobium species have different sugar compositions. Thus, the different strains of a single Rhizobium species are as different from one another as the different species of Salmonella and other gram-negative bacteria. This conclusion is substantiated by experiments demonstrating that antibodies to the lipopolysaccharide from a single Rhizobium strain can differentiate that strain from other strains of the same species as well as from other Rhizobium species. The role in symbiosis of the strain-specific O-antigens is unknown.     

Phenotypic exclusion in mouse melanoma-rat hepatoma hybrid cells: pigment and albumin production are not reexpressed simultaneously.

Hybridization of cells of defined and different histotypes has been carried out to investigate whether the expression (or reexpression) of parental functions is mutually exclusive, as is expected if the generally assumed rule of discreteness of differentiation applies to hybrid cells. A cross of pigmented mouse melanoma cells and albumin-producing rat hepatoma cells gave rise to hybrids containing essentially one set of chromosomes from each parent and producing neither melanin nor albumin. Cells of one hybrid clone are shown to retain the potential to reexpress both parental differentiations. Successive subclonings of this hybrid have shown that cells which reexpress one function may retain the potential to reexpress the other, and that freshly isolated, morphologically homogeneous subclones may produce pigment or albumin, but not both; there successive and exclusive shifts of phenotype are documented, and in these cases, chromosome loss is very slight. The use of immunoadsorbed antisera has revealed that most (if not all) of the albumin produced by the hybrid cells is of the mouse type. We conclude that both parental determinations are retained by the hybrid cells, and that the parental differentiations are reexpressed only in a mutually exclusive fashion.